Tropical Varieties for Exponential Sums

Abstract

We study the complexity of approximating complex zero sets of certain n-variate exponential sums. We show that the real part, R, of such a zero set can be approximated by the (n-1)-dimensional skeleton, T, of a polyhedral subdivision of Rn. In particular, we give an explicit upper bound on the Hausdorff distance: (R,T) =O(t3.5/δ), where t and δ are respectively the number of terms and the minimal spacing of the frequencies of g. On the side of computational complexity, we show that even the n=2 case of the membership problem for R is undecidable in the Blum-Shub-Smale model over R, whereas membership and distance queries for our polyhedral approximation T can be decided in polynomial-time for any fixed n.